Abstract:
Cold Spray is an emerging technology in the domain of additive
manufacturing. It is a solid-state high strain rate material deposition technique. It
uses a supersonic (2-4 Mach) impact of process gas (such as nitrogen or helium) to
deposit micron-sized (1-100 µm) metallic or composite powder particles onto a
substrate via a severe plastic deformation mechanism without any significant fusion.
To have a successful deposition, the specific powder particles should travel above a
material-dependent threshold velocity, which is called the critical velocity. The
convergent-divergent nozzle is employed for achieving high velocities. The main
objective of the current research is to study the flow visualization of two-phase
titanium particle laden nitrogen gas in a simulated 2-D axisymmetric nozzle where
particles are having a particle size of 25 microns, and to investigate the suitability
of a specific set of cold spraying process parameters for the successful deposition of
titanium powder using computational fluid dynamics. For the analysis, a twoequation realizable k-ε simulation viscous model was preferred due to its more
realistic consideration of the cold spray process and reduced computational cost.
Titanium powder particles will be successfully deposited using cold spray when
operated at the precise set of process conditions on account of the average particle
velocity observed at standoff distance higher than the critical velocity.
